Affiliation:
1. Beijing Computational Science Research Center Beijing 100193 China
2. Functional Crystals Lab Technical Institute of Physics and Chemistry Chinese Academy of Sciences Beijing 100190 China
3. School of Mechanical Engineering Chengdu University Chengdu 610106 China
4. Department of Physics Beijing Normal University Beijing 100875 China
Abstract
AbstractThe bulk photovoltaic effect, with ultra‐sensitive control under ambient piezo response, plays a significant role in many modern optoelectronic applications. However, functional bulk photovoltaic materials with high piezo sensitivity are rare, and discovering them is a great challenge. This article proposes a practical design scheme to achieve an ultra‐sensitive bulk piezophotovoltaic effect (BPPVE) in a single‐valley topological alloy material system. The BPPVE is accomplished by reversing the giant shift current in an alloy material that exhibits piezo‐sensitive topological band inversion, as predicted in the acentric single‐valley NaBa(P,Bi) alloy system. First‐principles calculations confirm that the shift current in NaBaP1‐xBix has high directional and magnitude sensitivity (−5000 to 400 µA V−2) in a rather low‐stress region (<0.5 GPa) near the critical alloy concentration (x ∼ 0.48), along with a remarkable topological phase transition. Notably, the stress‐induced bulk photovoltaic effect in NaBa(P,Bi) is much more sensitive than in other existing bulk photovoltaic materials. The outcomes demonstrate an outstanding BPPVE with ultra‐high piezo sensitivity for the first time in topological alloy systems.
Funder
National Natural Science Foundation of China
National Key Research and Development Program of China
State Key Laboratory of Low-Dimensional Quantum Physics